Serial accessed semiconductor memory with reconfigureable shift registers

ABSTRACT

A semiconductor memory is comprised of four arrays (10), (12), (14) and (16) that have the memory elements therein arranged in accordance with pixel positions on a display. The memory arrays have associated shift registers (34), (36), (38) and (40) which have data loaded in parallel and output in a serial format to the display. Each of the shift registers can be connected in a circulating fashion or a shift register of adjacent arrays can be cascaded. Switches (56), (58), (60) and (62) are provided for configuring the shift registers for either circulation or cascading of data. In the circulating mode, the input and output of the shift registers is multiplexed on one pin whereas in the cascaded configuration, one array receives a dedicated serial input and the other array in the cascaded pair outputs the serial output on a dedicated pin.

TECHNICAL FIELD OF THE INVENTION

The present invention pertains in general to semiconductor memories and, more particularly, to serial access semiconductor memories with shift registers output that are generally utilized as video RAMS.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is related to patent application Ser. No. 693,421, now U.S. Pat. No. 4,636,986, patent application Ser. No. 693,424, and patent application Ser. No. 693,422, now Pat. No. 4,648,077.

BACKGROUND OF THE INVENTION

In video systems, the information displayed is segmented into discrete elements referred to as "pixels", the number of pixels per unit area determining the available resolution. Each of these pixels for a simple black and white system can be defined in terms of one bit of data; whereas, a more complex system utilizing pixels having differing colors and intensity levels requires significantly more bits of data. To display the pixel information stored in memory, data is read from memory and then organized in an interim storage medium in a serial format. As each horizontal line in the display is scanned, the pixel data is serially output and converted to video information. For example, the stored data for each black and white pixel correspond to a predetermined position in the scan line and determines the video output for either a "white" level or a "black" level. The serial formatting of pixel data is described in U.S. Pat. No. 4,322,635, issued to Redwine, U.S. Pat. No. 4,347,587, issued to Rao and U.S. patent application Ser. No. 567,040 filed on Dec. 30, 1983, all assigned to Texas Instruments Incorporated.

In designing a video memory, two of the primary constraints facing the designer are the number of pixels required per scan line and the scanning rate. This determines how the pixel information is mapped into the memory and the rate at which the stored pixel information must be accessed and serially output. Typically, video memories are "pixel mapped" such that one row of memory elements or portion thereof directly corresponds to the pixel information of a given scan line or portion thereof. For example, in a black and white system having 256 pixels per scan line, a memory having 256 memory elements per row would be utilized. The information in the row is accessed and stored in a serial shift register for serial output therefrom during a given scan line, thereby requiring only one memory access per scan line. While data is being output from the serial shift register to the display, data is being accessed from the memory for updating of display data. This data is transferred to the shift register during the retrace period between adjacent scan lines. Therefore, the number of rows and columns of memory elements is determined by the number of pixels per scan line, the number of bits of information per pixel and the number of scan lines in the display. The operation of the serial shift register is described in more detail in U.S. Pat. Nos. 4,322,635 and 4,347,587, with a typical bit mapped video memory described in U.S. patent application Ser. No. 567,040, now U.S. Pat. No. 4,639,890.

In applications utilizing pixel mapped video memories, a large number of individual memories are arranged in arrays such that a single access operation outputs a predetermined pixel pattern. This allows a large number of pixels and/or bits per pixel to be output during a single access time, thereby reducing the time required to access a given set of information. This array configuration may require the shift registers associated with individual memories to be either cascaded or arranged in parallel.

To facilitate the use of multiple pixel mapped video memories, it is desirable to incorporate more than one memory on a single semiconductor chip. To provide a viable device from both an economical and a marketing standpoint, each of the integrated memories must maintain some degree of independent operation relative to the other memories on the same chip and yet share as many control functions as possible. This is necessary to reduce the number of integrated circuit pins required to interface between the peripheral circuitry and the chip itself and also to reduce the circuit density. When multiple pixel mapped video memories are integrated onto a single semiconductor chip, it is desirable to have independent access to the serial inputs and outputs of each of the memories and also to have independent control of the random Read/Write modes for the memories. This would require separate serial-in and serial-out interface pins for each memory, in addition to separate pins for the Read/Write control functions, resulting in an impractical multi-pin package. Additionally, the control circuitry required to provide the various independent functions would increase the density of the chip circuitry.

In view of the above disadvantages with integrated multiple memory semiconductor chips, it is desirable to provide a multiple memory chip having shared control functions utilizing a minimum number of pins to interface with peripheral circuitry, yet retaining a high degree of independent control of each of the memories in a given chip.

SUMMARY OF THE INVENTION

The present invention disclosed and claimed herein comprises a semiconductor memory for storing pixel information for video displays. The memory includes a first memory array and a second and separate memory array identical to the first memory array. Each of the memory arrays is comprised of a plurality of memory elements arranged in rows and columns. A row decoder is provided for selecting a row in both of the memory arrays and outputting this data stored therein through transfer gates to associated first and second serial shift registers. Each of the serial shift registers has a serial output and a serial input with the serial output of the first shift register connected to the serial input of the second shift register. The serial input of the first shift register is interfaced with external circuitry through a dedicated signal pin and the serial output of the second shift register is interfaced with the external circuitry through a dedicated signal pin. Therefore, the data in the first and second arrays, along with the first and second shift registers, is cascaded.

In another embodiment of the present invention, the first shift register has the input and output thereof multiplexed to a dedicated IC pin and the second shift register has the serial input and output multiplexed to a second dedicated signal pin. An external signal is provided for determining whether the serial inputs or the serial outputs are interfaced with the external circuitry. The circulating shift registers allow the data to be shifted out and back to the input thereof.

In yet another embodiment of the present invention, the cascaded shift registers and circulating shift registers are incorporated on the same semiconductor chip by utilizing mask programmable options wherein mask modifications are made prior to fabrication of the semiconductor device to select either the circulating shift register or the cascaded shift register arrangement.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following description taken in conjunction with the accompanying Drawings in which:

FIG. 1 illustrates a schematic block diagram of a semiconductor chip incorporating four pixel mapped memory arrays in accordance with the present invention;

FIG. 2 illustrates timing diagrams for writing data to select ones of the memory cells in accordance with the Write Mask feature;

FIG. 3 illustrates a block diagram of a symmetrical pixel memory array;

FIG. 4 illustrates a portion of the display map for the array of FIG. 3;

FIG. 5 illustrates a schematic block diagram of the shift register and tap latch;

FIGS. 6a and 6b illustrate a diagram of one scan line for three different display scans utilizing soft panning;

FIGS. 7a and 7b illustrate a diagram of one scan line for three different display scans with the shift register tapped at varying positions;

FIG. 8 illustrates a schematic diagram of one shift bit of the shift register;

FIG. 9 illustrates a schematic diagram of three serially connected shift bits;

FIG. 10 illustrates a schematic diagram of a portion of the serial shift register and the tap latch;

FIG. 11 illustrates a schematic block diagram of the interface between the tap latch, shift register and column decode circuits;

FIG. 12 illustrates a schematic block diagram of the preferred layout of the memory elements in the four pixel mapped memory arrays and the associated shift registers and tap latches;

FIG. 13 illustrates a timing diagram for transferring data from memory to the shift register;

FIG. 14 illustrates a timing diagram for shifting data from the shift register to memory;

FIG. 15 illustrates a schematic block diagram of the circuitry for individually addressing individual ones of the four arrays on the semiconductor chip;

FIG. 16 illustrates timing diagrams for individually addressing the memories with separate column address strobes;

FIG. 17 illustrates a schematic diagram of the circuit for midline load; and

FIG. 18 illustrates a timing diagram for midline load.

DETAILED DESCRIPTION OF THE INVENTION By Four Memory Array

Referring now to FIG. 1, there is illustrated a semiconductor memory comprised of four memory arrays 10, 12, 14 and 16 referred to hereinafter as a "By Four Memory Array." Each of the memory arrays 10-16 is comprised of a read/write memory organized with both serial access and random access, both of which may use a cell array of the Dynamic Random Access type. All of the arrays 10-16 are included on one semiconductor chip which is usually mounted in a standard dual-in-line package. Memories of this type are generally described in U.S. Pat. No. 4,081,701, issued to White, et al. and assigned to Texas Instruments Incorporated. Each of the arrays is generally split into two halves with an equal number of memory cells in each half to define distinct rows and columns of memory elements. A row of sense amplifiers, each associated with one column, is disposed between the two halves such that activation of one row provides an output on each of the sense amplifiers. Appropriate decoding circuits are then utilized to output all or select ones of the address data bits, as will be described hereinbelow.

Each of the memory arrays 10-16 is arranged in a "bit mapped" configuration; that is, the relative location of a bit of data stored in the memory corresponds to a physical location of a pixel on display. For example, the data stored in the first row and first column of one of the bit mapped arrays could correspond to the first pixel in the first scan line on the video display. If only one array were utilized, the adjacent pixel would correspond to the data stored in the first row and second column of the array. However, if multiple arrays are utilized, adjacent columns in a given array correspond to every nth pixel in the display where n is equal to the number of arrays in parallel. This type of memory is fully described in U.S. patent application Ser. No. 567,040, filed Dec. 30, 1983 and assigned to Texas Instruments Incorporated, "Inside Graphic Systems, From Top To Bottom", Electronic Design, Volume 31, No. 15 (1983), by Novak and Pinkham, "Dedicated Processor Shrinks Graphic Systems To Three Chips", Electronic Design, Volume 31, No. 16 (1983), by Williamson and Rickert and "Video Ram Excells At Fast Graphics", Electronic Design, Volume 31, No. 17 (1983), by Pinkham, Novak & Guttag.

The memory arrays 10-16 are all contained on a single semiconductor chip denoted by a dotted line. An address A0-A7 is received in an address buffer 18, the output of which is input to a row address latch 20 and a column address latch 22. The row address latch 20 is controlled by the row address strobe signal RAS and the column address latch 22 is controlled by the column address strobe CAS The row address latch 20 is output to a row address bus 24 and the output of the column address latch 22 is output to a column address bus 26. Each of the memory arrays 10-16 has associated therewith a row decoder 28 for receiving the latched row address from a row address bus 24 and a column decoder 30 for receiving the latch column address from the column address bus 26. Although the row and column decoders are shown separate, each of the arrays 10-16 shares a common row decoder and a common column decoder, as will be described hereinbelow.

Each of the memory arrays 10-16 has a data input/output (I/O) circuit 32 associated therewith which is comprised of I/O data lines. The I/O data lines associated with the array 10 are denoted by "I/O₀ ", the I/O lines associated with the array 12 are denoted by "I/O₁ ", the I/O lines associated with the array 14 are denoted by "I/O₂ " and the I/O lines associated with the array 16 are denoted by "I/O₃." In addition, a serial shift register 34 is associated with the array 10, a serial shift register 36 is associated with the array 12, a serial shift register 38 is associated with the array 14 and a serial shift register 40 is associated with the array 16.

Each of the shift registers 34-40 has associated therewith tap latches 42, 44, 46 and 48, respectively. The tap latches 42-48 are operable to select the shift bit of the associated shift registers 34-40, respectively for output therefrom. The tap latches 42-48 are interfaced with a tap latch bus 50 which is connected to the output of a tap latch decode circuit 52. The tap latch decode circuit 52 receives the latched column address from the address bus 26 for decoding thereof. In the preferred embodiment, the tap latch decode circuit 52 and the column decoder 30 are shared functions such that only one decode circuit is required. Control circuitry is provided for determining whether the decoded output is placed onto the tap latch bus 50 or the column decode bus 26, as will be described hereinbelow.

Each of the shift registers 34-40 is comprised of a plurality of serially arranged shift bits, each shift bit therein associated with a separate column in the associated array. A transfer gate 54 is provided for interfacing between the individual columns of each of the arrays 10-16 and the associated shift registers 34-40. This transfer of data can either be from the output of each of the sense amps in the respective memory arrays for loading into the shift bits of the respective shift registers or it can allow transfer of data from the shift register to the associated array. The transfer gates 54 allow for transfer of all of the data in the addressed row to the shift register for serial output therefrom, as will be described hereinbelow. The operation of the transfer gates and the serial shift register is described in detail in U.S. Pat. No. 4,330,852.

The output of the tap latch 42 comprises the serial output of the shift register 34, and this output is input to one input of a Single Pole Double Throw switch 56, which allows for the output of tap latch 42 to switch between the serial input of the shift register 34 and the serial input of the shift register 36. In a similar manner, the output of the tap latch 46, which is the selected output of the shift register 38, is also input to a Single Pole Double Throw switch 58, which selects between the serial input of the shift register 38 and the serial input of the shift register 40 associated with the array 16. The tap latch 44, which selects the output of the shift register 36, is fed back around to the serial input of the shift register 36 through a Single Pole Single Throw switch 60, and the output of the tap latch 48 is also fed back to the serial input of the shift register 40 through a Single Pole Single Throw switch 62. Each of the switches 56-62 is a metal mask programmable option which is selected during fabrication of the semiconductor memory. Although illustrated as switches, they are in actuality a series of lines which are connected or disconnected on the mask prior to fabrication of the device.

The switches 56-62 allow for two modes of operation. In the first mode, the switches 56 and 58 are connected such that the output of the tap latch 42 is connected back to the serial input of the associated shift register 34 and the output of the tap latch 46 is connected back to the serial input of the associated shift register 38. In a similar manner, the switches 60 and 62 are closed such that the outputs of the tap latches 44 and 48 are connected back to the serial inputs of the respective shift registers 36 and 40. In this manner, each of the shift registers 34-38 is configured as a "circulating" shift register.

In the second mode of operation, the switch 56 is configured to connect the tapped output of the shift register 34 to the serial input of the shift register 36 and the switch 58 is configured to connect the tapped output of the shift register 38 to the serial input of the shift register 40. The switches 60 and 62 are configured in the open position such that circulation of data in the shift registers 36 and 40 is inhibited. This second mode of operation essentially cascades shift registers 34 and 36 and shift registers 38 and 40.

To interface with the shift registers in two modes, a signal pin labeled "S₁ " is connected to the output of the tap latch 44, a signal pin "S₀ " is interfaced with the serial input of the shift register 34, a signal pin "S₂ " is interfaced with the serial input of the shift register 38 and a signal pin labeled "S₃ " is interfaced with the output of the tap latch 48. In the first mode of operation, the pin S₁ is multiplexed with both the serial input and output of shift register 36, pin S₀ is multiplexed with the serial input and output of shift register 34, pin S₂ is multiplexed with the serial input and output of shift register 38 and pin S₃ is multiplexed with the serial input and output of shift register 40. Buffers are provided such that data can be input or output to the associated shift registers on pins S₀ -S₃ in response to the serial out enable signal SOE to selectively input data or receive output data from the associated shift register. These multiplexed functions will be described hereinbelow with reference to FIG. 5.

In the second mode of operation, the pin S₁ is connected to the output of tap latch 44 and the pin S₀ is connected to the input of the shift register 34, the shift registers 34 and 36 being cascaded. Pin S₀ is connected to the input of shift register 38 and pin S₃ is connected to the output of tap latch 48, shift registers 38 and 40 being cascaded. In this mode, data can be serially input to shift register 34 and extracted from the tapped output of shift register 36. In a similar manner, data can be serially input to shift register 38 and extracted from the tapped output of shift register 40.

The switches 56-62 provide the option of selectively accessing each of the shift registers associated with the memory arrays 10-16 on a single multiplexed input/output or, alternatively, cascading the associated shift registers of two of the arrays with a dedicated input and a dedicated output for each cascaded pair. In this manner, only four pins on the integrated circuit package are required. Each of these configurations and the applications therefor will be described in more detail hereinbelow.

Each of the memory arrays 10-16, as described hereinabove, shares a common row decoder and a common column decoder. A row address and the associated RAS signal activates the addressed row in each of the arrays 10-16 and a column address and the associated CAS signal activates the addressed column on each of the arrays 10-16. Transfer of data can then be effected between the bit lines and either the data I/O circuits 32 or the shift registers 34-40. By sharing a common column and row decoder, a random Read or a random Write function would require reading or writing of data to all of the arrays 10-16 simultaneously. To selectively Write data to one or more of the arrays 10-16 could require separate column decode circuits and associated peripheral control circuitry. This would significantly increase the circuit density on a given chip. In accordance with the present invention, two methods are utilized for separately writing to a desired location in a select one of the memories of the four arrays 10-16 without disturbing data in the same location in the unselected one of the arrays. The first method is referred to as a "Write Mask" feature which inhibits writing to unselected arrays and the second method is referred to as "Separate CAS38 and utilizes separate column address strobes CAS₀, CAS₁, CAS₂ and CAS₃ to select the array to be written to. As will be described hereinbelow, both of these features are incorporated on the semiconductor chip but only one is activated during fabrication by altering the metal mask.

To selectively alter data in any of the arrays 10-16 or any combination thereof, an enable circuit 64 is provided for interfacing between and I/O buffer 66 and the I/O lines I/O₀ -I/O₃. The enable circuit 64 is controlled by outputs from an arbiter 68 which determines whether the Write Mask feature or the Separate CAS feature is utilized. If the enable circuit 64 is controlled to disable any of the I/O outputs associated with the arrays 10-16, the data on the associated bit line cannot be "written over." Only the enabled I/O lines can have the associated bit lines activated such that the associated memory element can have data written thereto.

In the Write Mask mode, the four data pins D₀ -D₃ are multiplexed such that enable signals W₀, W₁, W₂ and W₃ can be multiplexed therewith. The signals W₀ -W₃ determine which of the memory arrays 10-16 are to have the associated I/O ports enabled. The disadvantage to the Write Mask feature, as will be described in more detail hereinbelow, is that only one set of values for the signals W₀ -W₃ can be latched for each RAS signal. Thereafter, only locations in the selected arrays can be written to. This presents a problem when operating in the page mode.

When the metal mask is altered to select the Separate CAS feature, the arbiter 68 distinguishes between the four CAS signals. In this mode, the row is selected with the RAS signal and then the desired one of the CAS signals CAS₀ -CAS₃ is input thereto. Therefore, the column address and any one of the columns in the arrays 10-16 can be selected for a given row access. Only one row access is required to operate in the page mode and the CAS signals can be controlled during a given row access to select columns from any one of the arrays 10-16 or any combination thereof.

A clock and control generator 69 is also provided on the chip to generate the various clock signals and control signals such as that required to activate the transfer gate and the shift registers 34-40. Two of the signals input to the clock and control generator 69 are the signal for the shift register clock SCLK and the signal for the transfer and output enable signals TRQE.

Referring now to FIG. 2, there is illustrated a timing diagram for the Write cycle for the memory of FIG. 1 illustrating the Write Mask feature. In the conventional RAM, the row address is latched in the row address latch 20 as RAS goes low. After a predetermined duration, the column address is placed in the address buffer 18 and CAS goes low to latch the column address in the column address latch 22. In the Write mode, the Write/Enable signal WE is changed to a low level after the row address is latched. In the Write Mask feature, the WMWE signal goes low prior to RAS going low. This allows the arbiter 68 to latch any data on the data inputs, representing the signals W₀ -W₃. Since the masked data is latched only once for each change in RAS, only one set of masked data can be latched for each row address. As described above, this is a disadvantage when operating in the page mode, since different arrays cannot be selected during a given row address.

CASCADED SHIFT REGISTER

Referring now to FIG. 3, there is illustrated an array configured of four memories 70, 72, 74 and 76. Each of the memories 70-76 is similar to the memory of FIG. 1, in that four bit memory arrays are contained therein. The memories 70-76 are operated in the second mode of operation with cascaded shift registers. Each pair of cascaded shift registers therefore has a dedicated pin for the serial input to the cascaded pair and a dedicated pin for the serial output to the cascaded pair, requiring four pins on the integrated circuit package to interface with the cascaded pairs. For illustrative purposes, the two cascaded pairs in the memory 70 are cascaded with the two cascaded pairs in the memory 72. The two cascaded pairs in the memory 74 are cascaded with each other and the two cascaded pairs in the memory 76 are cascaded with each other. Regardless of the configuration, the electrical configuration is the same, with only the physical layout of the interconnects changing.

A data update circuit 78 is provided that receives a signal from a microprocessor (not shown) on a bus 80 to generate sixteen separate signals to control either the Separate CAS function of each of the memory arrays in the memory 70-76 or, alternately, the Write Mask feature. These outputs are labeled CAS_(a) /W_(a) -CAS_(p) /W_(p). These signals are associated with separate ones of the memory arrays in memories 70-76 to selectively write in the random mode to those arrays for updating pixel data, as will be described hereinbelow.

Each of the pixel mapped arrays in the memories 70-76 is labeled with a letter indicating its relative position in the array. One cascaded pair in memory 70 is labeled "D" and "H". This cascaded pair is cascaded with arrays "L" and "P" in the memory 72. The other array pair in memory 70 is labeled "C" and "G," which is cascaded with the other array pair in memory 72 labeled "K" and "0". The cascaded arrays in the memory 74 are labeled "B", "F", "J" and "N" and the cascaded arrays in memory 76 are labeled "A", "E", "I" and "M". Therefore, the array of FIG. 3 is configured such that arrays A, B, C and D are arranged in parallel, with the serial outputs thereof connected to four parallel inputs of a four-bit serial shift register 82, the serial output of which is processed for input to a display. The remaining cascaded arrays E-H, I-L and M-P are cascaded in a parallel configuration, such that all of the elements in the cascaded arrays A-D are output to the four-bit shift register 82, followed by all of the shift register data from the arrays E-H, etc. This is referred to as "symmetrical pixel mapping."

Referring now to FIG. 4, a portion of the video display is illustrated utilizing the symmetrical pixel array of FIG. 3. In accessing one row of data in the symmetrical array, a row address is first supplied and then a column address. The data on the bit lines of each column is then transferred with the transfer gate 54 to the respective shift registers of each of the arrays A-P. Once the data is parallel loaded into the respective shift register, all of the shift registers are clocked by a common shift clock to synchronously shift the data to the four-bit shift register 82. For a 256 bit wide array and a corresponding 256 bit wide shift register, each of the positions is labeled "00" through "255" corresponding to the particular column. The first shift bit output of each of the arrays A through P corresponds to the column address 00. The first data loaded into the four-bit shift register 82 is the data initially stored in column 00 of arrays A-D. After the data is loaded into the four-bit shift register 82, it is shifted out at a data rate four times that of the shift clock. Therefore, the first piece of data output from the four-bit shift register 82 is the data in column 00, row 00 of array A followed by the data in column 00, row 00 of array B. After data corresponding to column 00 of arrays A, B, C and D is output from the four-bit shift register 82 to form the first scan line, the data corresponding to row 00, column 01 is then loaded into shift register 82 to form the second scan line. This continues until all of the data in the shift registers associated with registers A-D is output, which requires 256 shift clocks and 1024 shifts of the four bit shift register 82.

In this example, the display is 256 blocks long which, for the first scan line, is comprised of 1,024 pixels. For the next scan line, the data from the shift registers initially associated with the arrays E-H has been serially loaded into the shift registers associated with the arrays A-D. This data is then serially loaded into the four-bit shift register 82. The next scan line associated with all of the data in the shift registers associated with arrays I-L and the fourth scan line is comprised of the data in the shift registers associated with the arrays M-P. This forms 256 pixel arrays each having the pixels therein labeled A through P. After all of the data associated with row address 00 is output from the shift registers, row 01 is accessed and the data transferred to the associated shift registers and scan lines five through eight are displayed to form the second row of pixel arrays.

By utilizing the symmetrical array of FIG. 3, it is possible to write over sixteen adjacent pixels in any one of the pixel arrays in one memory access time. If only one pixel mapped memory array were utilized, it would require sixteen memory accesses to change the data of the sixteen pixels. In the symmetrical pixel array, it is only necessary to make one random access of the memory arrays A-P, with the data update circuit 78 activated to select the array to be written over at that row and column address and in the desired pattern.

For example, if a pattern illustrated by the reference numeral 84 in FIG. 4 were to be drawn on the display, a conventional system would access each row defining the pattern 84 and change the column address to modify the appropriate pixel memory locations. This would require operation in the page mode for the memory. The row address would then be changed and this step repeated. The pattern 84 is comprised of the pixels H, L, and P in the pixel array in row 00, column 00, pixels E, F, J and N in the pixel array in column 01, row 00, the pixels D, H and L in the pixel array in column 00, row 01 and the pixels B, F, I and J in the pixel array in column 01, row 01. A conventional system would require six row accesses with each row access requiring two column accesses to write over all of the pixel data to form the pattern 84. However, in the symmetrical pixel mapping array of FIG. 3, only four accesses are required to form the pattern 84. The system would first access memory cells in row 00, column 00 of all of the memory arrays A-P and enable only memory arrays H, L, and P for writing to. With the Write Mask option selected for the memory 70-76 in FIG. 3, a new row access would be required prior to changing the enabled pixel arrays for row 00, column 01. However, if the Separate CAS option were selected, the page mode would be utilized and only one row access made for updating the pixel information in column 00 and column 01.

By utilizing cascaded shift registers internal to the semiconductor chip having four pixel mapped arrays contained therein, only four pins are required to provide the 4×4 array. This allows for any configuration requiring a symmetrical array that is two pixels wide or any multiple thereof. Therefore, a 4×4 symmetrical pixel array can be utilized, as illustrated in FIG. 3, or even a 16×16 pixel array can be utilized.

CIRCULAR SHIFT REGISTER WITH MULTIPLE TAPPED OUTPUT

Referring now to FIG. 5, there is illustrated a schematic block diagram of a 256 bit shift register 86 with an associated 256 bit tap latch 88 and an associated 256 element transfer gate 90. The shift register 86 is similar to the shift registers 34-40, the tap latch 88 is similar to the tap latches 42-48 and the transfer gate 90 is similar to the transfer gate 54 in FIG. 1. The transfer gate receives the bit lines B/L₀₀ -B/L₂₅₅ on the input and has the outputs thereof connected to the individual shift bits of the shift register 86 labeled "00" through "255," with the serial input being input to shift bit 255 and the serial output being output by shift bit 00. The tap latch 88 is operable to tap the serial output at any one of the shift bits 00 through 255.

The shift output from shift bit 00 is input to a tristate buffer 92, which has the output thereof connected to a Single Pole Single Throw switch 94. The switch 94 is similar to the switches 60 and 62. As described above, the switch 94 may not be utilized if the shift register is configured similar to shift registers 34 and 38 with the Single Pole Double Throw switches 56 and 58. The output of the switch 94 is connected to the serial input of shift bit 255. The output of the tap latch is input to a tristate buffer 96, the output of which is connected to one of the pins S₁ -S₃ which are referred to as "S_(i) " where "i" is equal from "1" to "3". The S_(i) pin is also input to a tristate buffer 98, the output of which is connected to the serial input of shift bit 255. This input is labeled SIN, whereas the output of the tap latch is labeled SOUT. The tristate buffers 92, 96 and 98 are controlled by the SOE signal. When the SOE signal is high, buffers 92 and 96 are disabled and buffer 98 enabled. This allows the pin S_(i) to serve as a serial input pin. When SOE is low, buffer 98 is disabled and buffers 92 and 96 enabled. This configures the shift register 86 as a circulating shift register with the output of shift bit 00 input back to shift bit 255 and the output of the tap latch connected to the pin S_(i). Pin S_(i), in this configuration, serves as one of the serial output pins. The switch 94 is only opened, as described above, when the mask option is selected wherein two shift registers in a single semiconductor chip are cascaded.

In the preferred embodiment, it is important to note that the serial output is always fed back from shift bit 00 to shift bit 255 and not from the output of the tap latch 88. However, it could be fed back from the tap point. With feedback from shift bit 00, the tap latch can be activated to select the output from any one of the shift bits in the shift register 86 without affecting the order in which the data circulates. For example, shift bit 64 could be selected as the output shift bit such that the first bit appearing on the output would be the data initially stored in shift bit 64, followed by the data initially stored in the remaining shift bits 65-255. However, as the shift clocks continue to shift data, the data stored in shift bit 255 is followed with the data initially stored in shift bit 00. In this manner, the initial order of the data stored in the shift register 86 can be maintained independent of the tap position.

A counter (not shown) counts the number of shift clocks to provide a count output. The external microprocessor which controls the memory provides a reset for the counter on transfer of data to the shift register 86 and then monitors the count. The microprocessor can then transfer data back to the memory at a predetermined count delayed by a predetermined number of shifts. For example, if it is desirable to shift all of the data in a given row of memory by one pixel, it would only be necessary to count 255 counts of the shift clock from the initial position and then transfer the data to the bit lines. This would effectively shift the data by one.

Referring now to FIGS. 6a and 6b, a select line of the display is represented for three separate frames of the display wherein a frame is defined as the time required to scan all of the lines on the display. The frames are referred to as FRAME1, FRAME2 and FRAME3 and the line that is illustrated is referred to as line "N." In the illustrated example, there are 256 pixels for each scan line of the display and a 256 bit wide memory associated shift register is utilized. After transfer of data to the shift register, the timing is such that 256 shifts are made to output all of data contained in the shift register onto the display for a given line. In FRAME1, the first pixel corresponds to shift bit 00 which also corresponds to the data stored in column 00. The last bit of data shifted out at the end of the scan line corresponds to shift bit 255, which also corresponds to column 255. In order to shift the data by one, the counter (not shown) counts the number of shift clock cycles and performs a transfer from shift register to memory at the row address corresponding to that line at a predetermined shift count. The example illustrated in FIG. 6a requires the transfer of data from the shift register to memory to occur after 255 shift clocks. At this count, the data originally in shift bit 00 will now be in shift bit 01. A transfer at a count of 255 will result in the data being shifted to the right by one pixel position corresponding to data being shifted to the next higher column address. Therefore, on the next frame, transfer of data from memory to the shift register results in this shifted data being output. If a transfer from shift register to memory occurs for every count of 255, the data will appear to shift to the right one pixel for every scan. Therefore, scan three for the same line will have the pixel shifted two pixels to the right with respect to FRAME1.

To shift one position to the left, the transfer of data from shift register to memory occurs after a shift count of one. This will result in the data originally in shift bit 00 being in shift bit 255 and the data initially in shift bit 01 being in shift bit 00, thus resulting in a shift to the left of one bit for each scan of the display. This is illustrated in FIG. 6b.

Referring now to FIG. 7a, there is illustrated three sequential frames of line N, similar to the frames of FIGS. 6a and 6b. However, in this example, the number of pixels on each line of the display is a multiple of 192 whereas the shift register and memory are 256 bits wide. The tap on the tap latch 88 is set to extract bits from shift bit 64 such that the first bit in the scan line will be data in shift bit 64 and the last pixel will correspond to data in shift bit 255. In order to shift the data by one to the right, the only change that is necessary is to change the tap from shift bit 64 to shift bit 63. This is evidenced in FRAME2 wherein the first pixel corresponds to data in shift bit 63 and the last bit of data corresponds to data in shift bit 254. On the next frame, indicated by FRAME3, the tap is again incremented down such that it is positioned at shift bit 62. By shifting the tap, the display can be "panned." However, the display can only be panned until the tap is positioned at shift bit 00 wherein the display will correspond to data between shift bit 00 and shift bit 191.

In order to display a constant changing background with a display having less pixels than that provided in the serial shift registers 86, the circulating shift register configuration can be utilized in conjunction with the tap latch 88. This is illustrated in FIG. 7b wherein the tap is set at shift bit 64 for the first frame, FRAME1, and then incremented to shift bit 65 and shift bit 66 in the next two successive frames, respectively. Since the shift register is a circulating shift register, 192 shifts from the shift bit 65 will cause the data stored in shift bit 00 to be output therefrom. In a similar manner, in FRAME3 tapping of the shift register 86 at shift bit 66 results in the data stored in shift bit 00 and shift bit 01 corresponding to the last two pixels in the line after shifting.

SHIFT REGISTER AND TAP LATCH

Referring now to FIG. 8, there is illustrated a schematic block diagram of a single shift bit in the shift register 86 of FIG. 5. The serial input is referred to as "IN" and the serial output is referred as "OUT". The serial input is connected to the gates of a P-channel FET 104 and an N-channel FET 106. The transistor 106 has the source thereof connected to V_(SS) and the drain thereof connected to the source of an N-channel transistor 108. The transistor 104 has the source thereof connected to V_(DD) and the drain thereof connected to the drain of a P-channel transistor 110. The drain of the transistor 110 and drain of the transistor 108 are connected to a node 112 and the gate of the transistor 110 is connected to SR1 and the gate of the transistor 108 is connected to SR2. As described above, SR1 and SR2 are the inverted and noninverted forms of the shift clock. Transistors 104-110 comprise the first stage of a shift bit. The second stage is comprised of P-channel transistors 114 and 116 and N-channel transistors 118 and 120. The transistors 114 and 120 are configured similar to transistors 104 and 106 and transistors 116 and 118 are configured similar to transistors 110 and 108, respectively. The gates of the transistors 114 and 120 are connected to the node 112 and the drain of the transistor 116 and the drain of the transistor 118 are connected to the serial output. A capacitor 122 is connected between the node 112 and VSS and a capacitor 124 is connected between the serial output and V_(SS). The capacitors 122 and 124 represent storage capacitance.

In operation, data is input on the capacitor 124 at the output of the shift bit which also connects it to the gates of the transistors 104 and 106. This data clocked through to node 112 when SR1 is low and SR2 is high. If the data is a logic low level, transistor 104 conducts and if the data is a logic high level, transistor 106 conducts. When SR1 returns to a high level and SR2 returns to a low level, the data is stored on the capacitor 122. To transfer data from node 112 to the serial output, SR1 is applied to the gate of transistor 118 and SR2 is supplied to the gate of transistor 116. Therefore, data is transferred when SR2 is low corresponding to SR1 being high. This is the opposite configuration than that with respect to transfer of data to node 112.

Referring now to FIG. 9, there is illustrated three shift bits 126, 128 and 130 connected in series. For each of the shift bits, transistors 104 and 106 are represented by an inverting amplifier symbol 132 and the transistors 114 and 120 are represented by an inverting amplifier symbol 134. In a transfer cycle, the bit line is connected to the serial output of each of the shift bits with SR1 being low and SR2 being high. This effectively connects the data on the bit line to the input of the amplifier 134 for the next successive shift bit. The bit line (not shown) is then disconnected, with the signal being stored on the capacitor 124. When the shift clock changes states, the signal on the output of the respective shift bit is transferred to the output of the next shift bit.

Referring now to FIG. 10, there is illustrated a schematic diagram of the shift bits 255, 254 and 253 in a 256 bit shift register, with the serial input being input to the shift bit 255. The outputs of each of the shift bits are input to NAND gates 133, the other input of which is connected to a tap latch signal corresponding to the output of the tap latch decode circuit 52. The output of each of the NAND gates 133 is connected to the drain of a pass transistor 135, the source of which is connected to a line 136. The gate of the each of the transistors 135 associated with each of the shift bits is connected to the tap latch signal. For example, the tap latch signal associated with the shift bit 255 is TP255, the tap latch signal associated with the shift bit 254 is TP254 and the tap latch signal associated with the shift bit 253 is TP253.

The NAND gates 133 are each comprised of an N-channel transistor 138 having the source thereof connected to V_(SS), the drain thereof connected to the source of an N-channel transistor 140 and the gate thereof connected to the tap latch signal. The transistor 140 has the drain thereof connected to the drain of P-channel transistor 142 and the gate thereof connected to the output of the respective shift register. The transistor 142 has the source thereof connected to V_(DD) and the gate thereof connected to the output of the shift register associated therewith. When the tap latch signal is present, the transistor 138 provides a low resistive path to V_(SS) and the output on the drain of the transistor 140 is a function of the shift register output. Although not a true NAND function, when the transistor 138 is turned off, the associated pass transistor 135 is also turned off. The NAND function provided by this configuration reduces power drain of unselected taps.

The latch circuit for generating the latch signals TP255-TP00 is comprised of cross coupled inverters 144 and 146, each having the output connected to the input of the other for storing a logic state thereon. The input of the inverter 144 and output of the inverter 146 are connected to a node 148. The node 148 is connected to the drains of an N-channel transistor 150 and a P-channel transistor 152, the sources of which are connected to a decode line Y255 corresponding to the column address 255. The node 148 is connected to the gate of the pass transistor 134 through a series resistor 154. The gate of the transistor 150 is connected to a latch signal LCH and the gate of the transistor 152 is connected to the inverted latch signal LCH. In operation, the presence of the LCH signal and the decode signal causes a high logic signal to be latched in the cross coupled inverters 144 and 146, thus storing the latch signal TP255 therein.

The shift bit 254 has an associated cross coupled inverter pair 156 and 158 and the shift bit 253 has an associated cross coupled inverter pair 160 and 162. The decode signal Y254 is input to a parallel pair of N- and P-channel transistors 164 and 166 and the decode signal Y253 is input to the cross coupled inverter pair 160 and 162 through a pair of N- and P-channel transistors 168 and 170. Series resistors 172 and 174 are provided for the shift bits 254 and 253, respectively.

In an important aspect of the present invention, the tap point is determined by an address which is decoded by the column address decoder. Therefore, only one decoder is required to both address a column and also address the particular tap point that constitutes the serial output of the serial access shift register. This significantly reduces the amount of circuitry required to provide the decode function for the tap of the shift register. Prior systems have utilized a separate decoder to determine which of the taps is to be selected. In addition, each shift bit in the register can be selected, thus providing more versatility for various applications.

Physical Layout

Referring now to FIG. 11, there is illustrated a schematic block diagram of the chip innerconnections and the approximate physical layout of the memory array 10 and associated transfer gate 54, shift register 34, tap latch 42 and column decoder 30. For illustrative purposes, only column 00 and column 01 are illustrated with their associated output circuits. Column 00 outputs an inverted and noninverted bit line for the column address 00 with B/L 00 connected to the drain of an N-channel transistor 176 and B/L ₀₀ connected to the drain of an N-channel transistor 178. The source of the transistor 176 is connected to the I/O line labeled I/O₁ and the source of the transistor 178 is connected to the inverted I/O line labeled I/ ₁. The gates of the transistors 176 and 178 are both connected to the column decode line 00 for activation thereof when column address 00 is selected. In a similar manner, an N-channel transistor 180 is connected between bit line B/L 01 and the I/O line, and an N-Channel transistor 182 is connected between B/L₀₁ and I/O₁ line. The gates of the transistors 180 and 182 are connected to the column decode line 01.

The transfer gate 54 is comprised of a pass transistor 184 having the drain thereof connected to the noninverted bit lines and the source thereof connected to the input of the respective shift bit. The gates of all the transistors 184 in the transfer gate circuit 54 are connected to the transfer control signal SCT. The tap latch 42 provides a latch for each shift bit and it is controlled by the column decode line associated therewith. For example, column decode line 00 is connected to the control input of tap latch TL00. The output of tap latch TL00 is input to the gate of a pass transistor 186, the drain of which is connected to the output of shift bit 00 and the source of which is connected to the SOUT line. A similar pass transistor 188 is connected between the output of shift bit 01 and the SOUT terminal, with the gate thereof connected to tap latch TL01.

Referring now to FIG. 12, there is illustrated the preferred embodiment of the physical layout of the memory of FIG. 1, with each of the memory arrays 10-16 having 256 rows and each of the associated shift registers 34-40 having 256 shift bits. Like numerals refer to like parts in the various Figures. The memory arrays 10 and 12 are combined into arrays 190 and 192. The array 190 contains column 00 through column 127 and array 192 contains column 128 through column 255. Each of the arrays 190-196 contain one half of columns of memory cells corresponding to two of the I/O lines I/O₀ -I/O₃. The columns are intertwined such that columns having the same address are adjacent to each other. For example, column 00 of array 10 is the first physical column in array 190 and column 00 of array 12 is the second physical column in array 190. The I/O line is indicated by the subscript "0" for array 10 and "1" for array 12 and each is associated with the appropriate column address. An array 194 and an array 196 are provided on the other side of the semiconductor chip and comprise the columns of elements in the memory arrays 14 and 16, with the array 194 containing column 0 through column 127 and array 196 containing column 128 through column 255. Although not shown, the arrays 190 and 192 and arrays 194 and 196 are separated by the row decoder.

The shift registers 34 and 36 associated with the arrays 10 and 12 are disposed adjacent the arrays 190 and 192, with the shift bits associated with the respective columns and connected thereto. The transfer gate circuits 54 are not illustrated for simplicity purposes. The shift registers 38 and 40 are disposed adjacent the arrays 194 and 196 with the shift bits therein connected to the outputs of the respective columns. The shift registers 34-40 are divided into two halves, one half associated with the arrays 190 and 194 for shift bits 00 through 127 and the other half associated with arrays 192 and 196 for shift bits 128 through 255.

The tap latches 42 and 44 are combined into one tap latch 198 that is disposed between the column decoder 30 and the shift registers 34 and 36. The tap latches 46 and 48 are combined into one tap latch 200 disposed between the column decoder 30 and the shift registers 38 and 40. The random access I/O circuit and transfer gates are disposed between the shift registers and the respective arrays 190-196, as illustrated in FIG. 11.

Referring now to FIG. 13, there is illustrated a timing diagram for transferring data from the memory to the associated serial shift register. To effect this transfer, it is necessary for the TR/QE signal to be at a low level when RAS changes to a low level. The W signal goes high to indicate the Read Transfer operation for transferring data from memory to the shift registers and then RAS goes low to select the appropriate row address. After a predetermined duration of time, the bit lines separate and the data is stored in the output of the associated sense amps of each of the columns. The TR/QE signal then goes high, thus generating the SCT signal to the transfer gates 54 and connecting the bit lines of each column with the associated shift bit in the shift register. The rising edge of TR/QE also determines the minimum amount of time before the rising edge of the next shift clock signal SCLK occurs, as indicated by a causality arrow 202. In the preferred embodiment, this is approximately 10 ns. This places the data from the bit lines on the input of the shift bits, thus loading the data therein. On the rising edge of SCLK, the data is transferred to the output of the shift bit, as indicated by the causality arrow 204. On the rising edge of TRQE, all of the old data is removed from storage in the shift bits and new data is stored therein. However, the first bit of data is not shifted out until a predetermined duration of time after the rising edge of SCLK occurs.

Referring now to FIG. 14, there is illustrated a timing diagram for transferring data from the shift register to storage in memory. This data can either be input on the serial input, shifted in and then transferred to memory or it can be shifted from one row in the memory to the shift register and then transferred back into memory in a different row. To initiate a transfer between the shift register and memory, TR/QE goes low before RAS. The W signal is also low to indicate a Write Transfer operation for transferring data from the shift register to the memory. RAS then goes to a low level to read the row address and initiate the Write Transfer operation and also inhibit the shift clock. After a predetermined duration of time, TR/QE goes high to initiate data transfer and connect the outputs of the shift bits with the respective bit lines. The data present in the shift bits will then be transferred to the bit lines, sensed, latched by the internal sense amplifiers (not shown) and stored in memory. The shift clock will then be restarted after a predetermined duration of time relative to the occurance of the rising edge of the transfer signal. The rising edge of the shift clock may be delayed to ensure complete transfer of data prior to shifting. In the timing diagram illustrated in FIG. 14, the memory is configured such that the S₀ -S₃ pins are multiplexed for both SIN and SOUT. Therefore, the SOE signal must be a high signal level to input data to the respective shift register.

Write Mask/Separate CAS

Referring now to FIG. 15, there is illustrated a schematic block diagram of the enable circuit 64, I/O buffer 66 and arbiter 68 of FIG. 1 for distinguishing between the Separate CAS inputs CASO₀ -CAS₃ and the Write Mask feature. The I/O buffer 66 is comprised of separate 1/O buffers 208, 210, 212 and 214 which are connected to the W₀ /D₀ -W₃ /D₃ inputs. The I/O buffers 208-214 are operable to receive or output only data. The W₀ -W₃ signals are each input to a separate Single Pole Double Throw switch 216, of which only one is shown. The output of the switch 216 is connected to the data input of a D-type flip-flop 218, with the switch 216 being operable to switch the data input between ground and the respective W₀ -W₃ input. For simplicity purposes, only the circuitry associated with the W₀ input will be described. The clock input of the flip-flop 218 is connected to a clock signal φR1 and the clear input thereof is connected to a signal φ R1. φR1 is RAS delayed by a predetermined amount of time. This delay is provided by a noninverting circuit 220 and φR1 is provided by an inverting circuit 222. The Q-output of the flip-flop 218 is the signal W₀ '. The remaining outputs of the flip-flops not shown will be W₁ ', W₂ ' and W₃ '.

The W₀ ' signal is input to an arbitration circuit 224 to both determine which of the Write Mask or Separate CAS features is selected during fabrication of the memory and which of the I/O circuits 208-214 are to be enabled with the enable circuit 64.

The CAS₀ -CAS₃ signals are input to one input of a switch circuit 226 comprised of four Single Po1e Double Throw switches, the outputs of which are connected to separate inputs of a four inverter circuit 228. Each of the CAS₀ -CAS₃ signals is associated with one Single Pole Double Throw switch in the switch circuit 226 which is operable to switch the output between V_(SS) and the CAS₀ -CAS₃ signals. The output of each of the inverters in the inverter circuit 228 is labeled W₀ ", W₁ ", W₂ " and W₃ ", corresponding to each of the CAS₀ -CAS₃ signals. For simplicity purposes, only the circuitry associated with the W₀ " circuit will be illustrated. This signal is input to the arbitration circuit 224.

The CAS₀, CAS₁ and CAS₂ signals are input to Single Pole Double Throw switches 230, 232 and 234, respectively. The output of the switches 230-234 is input to separate inputs of a four input NAND gate 236. The CAS₃ signal is input to the remaining input of the four input NAND gate 236. The switches 230-234 are operable to connect the three associated inputs of the NAND gate 236 with either the respective CAS₀ -CAS₂ signals or V_(DD). These switches, in conjunction with the switches in the switch bank 226, are associated with the Mask Write option which is determined during fabrication of the semiconductor device. If the device is to be controlled by separate CAS signals, the switches 230-234 and the switches in the switch bank 226 will be disconnected from V_(DD) and connected to the respective CAS₀ -CAS₃ signals. In a similar manner, the switches 216 associated with the W₀ -W₃ signals will be connected to ground. The position of all mask programable switches in FIG. 15 is illustrated for the Separate CAS feature. For operation in the Write Mask mode, the opposite position of all the switches will be selected during fabrication of the device. However, it should be understood that these devices can be user selectable without requiring a permanent implementation in the metal mask.

The high output of the NAND gate 236 is present whenever any of the CAS₀ -CAS₃ signals go low. Since no switch is associated with the CAS₃ signal, this constitutes the CAS input when the Write Mask feature is selected and the switches 230-234 are connected to V_(DD). The output of the NAND gate 236 is input to one input of a three input AND gate 238, one input of which is connected to the φR2 signal and the remaining input of which is connected to the WM/WE input through an inverter 240. The φR2 signal is generated by delaying the φR1 signal through a buffer 223. The output of the AND gate 238 constitutes the Write signal and this signal is input to the arbitration circuit 224. The Write signal is generated whenever one of the CAS₀ -CAS₃ signals is low, when the WM/WE signal is low and when the φR1 signal is generated.

The WM/WE signal is also input to the D-input of a D-type flip-flop 242 which constitutes the Write Mask latch. The clock input of the flip flop 242 is connected to the φR1 signal and the preset input thereof is connected to the φR1 signal. The Q-output of the flip-flop 242 is labeled WM' and the Q-output is labeled WM'. Whenever the signal on the WM/WE input goes low prior to generation of the φR1 signal, this data is clocked through to the output, which corresponds to selection of the Write Mask feature. Whenever a standard Write function is being performed, the signal on the D-input of the flip-flop 242 goes low after RAS falls low and φR1 is generated. The state of the outputs on the flip-flop 242 does not change in this condition.

The WM' signal is input to one input of an AND gate 244, the other input of which is connected to the Write signal output by the AND gate 238. The output of the AND gate 244 is labeled EN to indicate an enable function and is input to the arbitration circuit 224. The WM' signal output from the flip-flop 242 is also input to the arbitration circuit 224.

The arbitration circuit 224 is comprised of a Single Pole Double Throw switch 246 which receives the W₀ ' and W₀ " signals with the output thereof connected to one input of a three input AND gate 248. The switch 246 is a mask selectable option similar to the switch 216, the switches in the bank 226 and the switches 230-234 are programmed during fabrication. The switch 246 is operable to select between the W₀ " and W₀ ' signals for input to the AND gate 248. When the Write Mask feature is selected, the W₀ ' signal is selected by the switch 246 and when the separate CAS feature is selected, the W₀ " signal is selected. The other two inputs of the NAND gate 248 are connected to the Write signal and V_(DD). The output of the AND gate 248 is connected to one input of an OR gate 250, the other input of which is connected to the EN signal output by the AND gate 244.

In operation, the arbitration circuit 224 provides an output from the OR gate 250 in response to one of the CAS₀ -CAS₂ signals being present or the Write Mask feature being selected. With the Write Mask feature, the signal on the input of the WM/WE terminal must be latched into the D-type flip-flop 242 to output a high signal for the WM' signal from the Q-output of the flip-flop 242. The WM/WE signal also places a high signal on AND gate 238. Subsequent generation of the Write signal on the output of the AND gate 238 raises two inputs of the three input AND gate 248 to a high signal level. When the W₀ signal is present and latched into the flip-flop 218 to generate a W₀ ' signal, the output of the AND gate goes high, thus raising the output of the OR gate 250 to a high level. In the separate CAS mode where the Write mask feature is deselected, the presence of a logic low level on any one of the CAS signals causes the output of the NAND gate 236 to go to a high level and this will cause the Write signal on the output of the AND gate 238 to be generated whenever a Write signal is present on the WM/WE input and φR1 is generated in response to RAS being generated. Since the switches 243 and 245 in the Separate CAS mode are switched away from the outputs of the flip-flop 242, one input of the AND gate 244 is low, maintaining EN signal low and the input of the AND gate 248 associated with the switch 245 is maintained at a high signal level. Therefore, AND gate 248 is controlled by the Write signal and the W₀ " signal switched through the switch 246. Therefore, the arbitration circuit 224 only produces an output from the OR gate 250 in response to the W0" signal.

The output of the R gate 250 of the arbitration circuit is input to a tristate buffer 252 which is part of the enable circuit 64 and is connected to the I/O buffer 208 associated with the D₀ line. The tristate buffer 252 is utilized only for incoming data with a buffer 254 providing for outgoing data. Only the incoming data is buffered with tristate buffer 252 which is controlled by the arbitration circuit 224. In a similar manner, arbitration circuits 256, 258 and 260 are associated with tristate buffers 262, 264 and 266 for selectively enabling incoming data from the buffers 210, 212 and 214, respectively. The arbitration circuits 256-260 are similar to the arbitration circuit 224 and they are controlled by the W₁ "-W₃ " signals, the W₁ '-W₃ ' signals or the EN signal. The EN signal is present when the Write Mask feature is available but not enabled in which case all four I/O buffers 208-214 are enabled. Each of the arbitration circuits 256-260 has a mask programmable switch internal thereto similar to the switch 246 in arbitration circuit 224.

Referring now to FIG. 16, there is illustrated a timing diagram for the Separate CAS feature. In utilizing the Separate CAS feature, RAS goes low to select the row address. Thereafter, one or more of the CAS₀ -CAS₃ signals goes low to load a column address into the column address latch. Additionally, the CAS₀ -CAS₃ signals determine which of the I/O buffers is enabled to allow writing of data to the selected column in the selected row. When selected, data is written to that column position in the selected one of the arrays and then CAS returns to a high level. For illustrative purposes, the first column address is associated with all four signals CAS₀ -CAS₃ going low at time T₁. The CAS signals return back to a high signal level at time T₂. With RAS remaining low, another column address is placed onto the address lines A0-A7 and CAS₀ and CAS₂ change to a low level at time T₃. This results in only two of the I/O buffers being enabled for writing data to only two of the array positions. The CAS₀ and CAS₂ signals go back to a high level at time T₄ and then another column address is latched into the column address latch at time T₅ when CAS₁ and CAS₂ go low. This allows only writing of data to the array associated with the CAS₁ and CAS₂ signals.

By utilizing the Separate CAS option, as compared to the Write Mask option, the memory can be operated in the page mode whereby a single row is selected and then the column address changed and a Write performed after each column is accessed. This allows updating of the pixel information in multiple arrays on the single chip which shares a common column and row decoder. Without the circuit described in FIG. 15, separate column decodes would be required for each array on the chip, thus increasing the density and complexity of the semiconductor circuit.

Midline Load

When data is transferred from memory to the serial shift register, it is important that all of the data in the shift register first be output to the display or storage elsewhere prior to reloading the shift register. Normally, this presents no problem since the shift register is mapped to the number of pixels in a given scan line. For example, a 256 bit shift register would map directly onto a display having a line width 256×n pixels across where n is some integer. The transfer from memory to shift register could then occur during the retrace time, thus providing sufficient time to ensure that all data is out of the shift register and to load the shift register with new data.

Heretofore, the shift clock was inhibited during the retrace time and during transfer of data from the memory to the shift register and then allowed to initiate shifting upon beginning of the next scan line. However, some displays have a pixel length for each scan line that is not a multiple of the width of the shift register. For example, a pixel length of 960 would require a 960 bit wide memory. If a symmetrical array of four serial access memorys were utiltized, each having a 256 bit wide shift register associated therewith, only 240 of the shift bits in each of the shift registers would be required for a scan line. The remaining sixteen bits in each of the shift registers would either have the data therein discarded or output as the first sixty four pixels on the next scan line. However, this would require transfer of data from the memory to the associated shift register during the middle of a scan line. A conventional scan rate is approximately 12 ns per pixel. This would require the shift registers to shift data through at a 48 ns rate. The data must therefore be loaded within 48 ns. The time required for data to be transferred to the shift bits from the bits lines is approximately 5 ns-10 ns for a conventional memory. If a sufficient time is not allowed for the data to be transferred from the bit lines to the inputs of the respective shift bits, the data may be invalid. Therefore, the timing relationship between the initiation of the transfer cycle and the next data shift is important to effect a proper transfer of data during one shifting cycle.

The clock and control generator 69 in the memory of FIG. 1 provides the circuitry for effecting a proper transfer of data without requiring the user to place exacting requirements on his timing relationship for the TR signal and the shift clock. That is, the circuit of the present invention is tolerant to slight timing deviations in the TR signal with respect to the last cycle of the shift clock. This tolerance allows the TR signal to occur before or after the optimum time for the occurrence of the actual transfer sequence, as will be described hereinbelow.

Referring now to FIG. 17, there is illustrated a schematic diagram of the circuitry for the midline load feature. The TR signal is input through to inverters 280 and 282 to a node 283 labeled TR' and through an inverter 284 to the D-input of a flip-flop 286 which is the transfer latch. The Q-output of the flip-flop 286 is labeled TRL and a Q-output is labeled TRL. The flip-flop 286 is clocked by signal RASI which is an internal version of the RAS signal. As will be described hereinbelow the RASI signal is identical to the RAS signal upon initiation, but RASI can be controlled to remain low for a predetermined duration of time after RAS has gone high. RASI gives rise to signals φR1' and φR1' which are similar to signals φR1 and φR1, as described with reference to FIG. 15. The preset input of flip-flop 286 is connected to the signal φR1'. The TRL output is connected to one input of a three input AND gate 288, one input of which is connected to the node 283 which is the TR' signal. The output of the AND gate 288 is connected to one input of a NOR gate 290, the output of which comprises the STP signal, which is the signal that stops or inhibits the shift clock. The other input of the NOR gate 290 is connected to a delayed transfer signal XFRD. The XFRD signal is connected to the inverted input of the AND gate 288. The delayed transfer signal XFRD is generated from a transfer signal XFR and delayed through a delay gate 292. The XFR signal is generated on the output of a NAND gate 296. The NAND gate 296 has one input thereof connected to the inverted XFRD signal, one input thereof connected to a signal "XBOOT" and the remaining input thereof connected to the output of the AND gate 288. The XBOOT signal is a signal which is generated in conventional dynamic memories to boot the word line above V_(DD). Therefore, the output of the NAND gate 296 is low when a transfer sequence has been initiated and XBOOT goes high. The output of the NOR gate 294 is high only when both the output of the inverter 284 and the output of the NAND gate 296 are low, thereby preventing the generation of the transfer signal until XBOOT has occurred. Since XBOOT does not occur until the bit lines have had sufficient time to separate to a predetermined level, the bit lines will not be connected to the inputs of the shift bits until the bit lines have stabilized. This prevents invalid data from being generated due to the occurrence of a transfer signal prior to the time that the bit lines have stabilized.

The WE signal is input to the D-input of a flip-flop 298, the Q-output of which is labeled SRW and the Q-output of which is labeled SRW. The flip-flop 298 is clocked by the φR1' signal and the preset input is connected to the φR1' signal. The SRW signal is changed to a high level only when the WE signal is low prior to the occurrence of RASI going low. The SRW high signal indicates a Read Transfer wherein data is transferred from the memory to the shift register and the SRW high signal indicates a Write Transfer where data is transferred from the shift register to memory. In the Read Transfer mode, it is necessary to select the Word Line and then perform a transfer whereas in the Write Transfer mode, it is necessary to select SCT first, and then perform the transfer via the word line.

The SRW signal is input to one input of an NAND gate 300 and one input of a NAND gate 302. The other inputs of the NAND gates 300 and 302 are connected to the TRL signal. The SRW signal is connected to one input of a NOR Gate 304 and one input of an OR gate 306. The other inputs of the NOR gate 304 and OR gate 306 are connected to the TRL signal. The output of the NAND gate 300 is connected to one input of AND gates 308 and 310. The output of the NOR gate 304 is connected to one input of AND gates 312 and 314. The AND gates 308 and 314 have the other inputs thereof connected to a signal AX₀ and the AND gates 310 and 312 have the other inputs thereof connected to a signal AX₀. The signal AX₀ is controlled by the least significant bit of the row address signal. The output of the AND gate 308 is connected to the enable input of a tristate buffer 316, the output of the AND gate 310 is connected to the enable input of a tristate buffer 318. The output of the AND gate 312 is connected to the enable input of the tristate buffer 320 and the output of the AND gate 314 is connected to the enable input of a tristate buffer 321. The outputs of the buffers 318 and 320 are connected together and labeled X1A and the outputs of the buffers 316 and 321 are connected together and labeled X1B. A signal labeled X₁ is input to the buffers 316 and 318 and the XFER signal from the output of the NOR gate 294 is connected to the inputs of buffers 320 and 321. The signal X1 represents the Word Line driver signal which is normally generated in the conventional circuit. The output of the NAND gate 302 is connected to the enable input of a tristate buffer 322 and the output of the OR gate 306 is connected to the enable input of a tristate buffer 324. The buffer 322 receives the XFR signal on the input thereof and generates the SCT signal for connection to the transfer gate 54 and the buffer 324 receives the X1 signal on the input thereof to generate the SCT signal on the output thereof to the transfer gate 54.

In operation, the presence of the SRW low signal indicates a Read Transfer and requires the Word Line to be high before the transfer signal occurs. The output of NAND gate 300 will be high, thus enabling AND gates 308 and 310. The output of NOR gate 304 will be low, disabling AND gates 312 and 314. AND gates 312 and 314 control the buffers 321 and 320 to select the XFR signal as a function of the state of AX₀ and AX₀. In the Write Transfer mode where SRW is high, the output of NOR gate 304 is high and the output of NAND gate 300 is low, deselecting AND gates 308 and 310 which control the operation of buffers 316 and 318. The transfer signal SCT is controlled as a function of the XFR signal or the X1 signal by the state of the OR gate 306 and the NAND gate 302. The OR gate 306 outputs a high signal when either the SRW signal is high or the TRL signal is high. The NAND gate 302 outputs a high logic signal when either TRL is low or SRW is low.

Whenever the transfer signal occurs, it is necessary to maintain the SCT signal active for a predetermined period of time in order to allow sufficient time for the data to be transferred to or from the inputs of the respective shift bits. To provide for late occurrence (relative to RAS going high) of the TR signal, RAS is delayed from going from a low level to a high level for a predetermined duration of time. This is an internal function and does not affect the actual logic level of RAS external to the semiconductor memory. An inhibit circuit 326 is provided that is disposed in series with the RAS signal and the remaining RAS control signals to the semiconductor chip. As described above, this is denoted as RASI. RAS is also input to one input of an AND gate 328, the other input of which is connected to the TR signal output from the inverter 284. The output of the AND gate 328 is input to a delay circuit 330, the output of which controls the inhibit circuit 326. The AND gate 328 outputs a signal when RAS goes high and TR goes high, indicating that a transfer is taking place. RAS is inhibited from going high with respect to the remainder of the circuit until a predetermined duration of time after the rising edge of TR has occurred. If the rising edge of TR occurs a sufficient amount of time prior to the rising edge of RAS, the rising edge of RASI is coincident with the rising edge of RAS. RASI is also input to invertor 331 to generate φR1' and buffer 333 to generate φR1'.

Referring now to FIG. 18, there is illustrated a timing diagram for loading of data from the memory to the shift register. When the rising edge of TR occurs, it gives rise to the SCT signal, as indicated by an arrow 332. However, the SCT signal cannot be generated until the XBOOT signal is generated, as indicated by the input signals to the NAND gate 296 in FIG. 17. Therefore, the transfer cannot begin until the bit lines have sufficiently separated. Since XBOOT does not occur until after the bit lines begin to separate, this will ensure that a transfer operation is not initiated prior to separation of the bit lines. The rising edge of the TR signal also changes the state of the stop clock signal STP to a low level, as indicated by an arrow 334. This signal remains low until the physical transfer of data is complete and then changes to a high signal level. While the stop clock signal is at a low logic level, the leading edge of the next clock signal in the SCLK waveform will be inhibited. However, if the rising edge of TR occurs a sufficient amount of time prior to the leading edge of the stop clock signal, the occurrence of the leading edge of the SCLK signal will not be affected. The rising edge of the SCLK signal will cause data to be shifted through the shift bits and the new data to appear on the output of the shift register, as indicated by the SOUT signal.

When the TR signal occurs early, it is necessary to prevent the SCT signal from being generated until after the bit lines have stabilized. The early transfer signal is indicated by a rising edge 336 on the TR waveform. This occurs prior to the time at which the bit lines have sufficiently separated. However, the SCT signal is not generated until the rising edge 338 of XBOOT occurs. At this time, the SCT signal is generated, as indicated by a dotted line. The delay of the SCT signal is indicated by "D1".

When the rising edge of the TR waveform occurs late, it is necessary to maintain the SCT signal active and the bit lines separated for a predetermined amount of time to allow transfer of data to the shift bits before the cycle ends. In addition, it is also necessary to inhibit serial shifting of data in the shift register until complete transfer of data to the shift register has occurred. The late transfer signal is indicated by a rising edge 340 on the TR waveform which gives rise to a falling edge 342 on the STP waveform. As described above, the rising edge of the next SCLK signal cannot occur until the STP signal has again returned to a high level. This is indicated by a rising edge 344 which allows the SCLK signal to go high, as indicated by a rising edge 346. The duration of time between the falling edge 342 and the rising edge 344 allows sufficient time for the data to be transferred from the bit lines to the respective shift register. This must occur prior to generation of the leading edge of SCLK which clocks the new data out onto the output of the shift register. In addition to maintaining SCT on, it is also necessary to maintain the bit lines in the proper data state which is accomplished by delaying the internal change of RASI from a low to a high level. This is indicated by an arrow 348 which is the result of the inhibit circuit 326, described above with reference to FIG. 17.

In summary, there has been provided a semiconductor memory which utilizes four pixel mapped memories having the bits therein mapped to locations directly corresponding to pixels on a display. Each of the memory arrays has a serial shift register associated therewith and transfer gates for transfer of data therebetween. The serial shift register can either be connected in a circulating fashion with either serial in access or serial out access to each of the shift registers requiring only one pin per shift register. Alternately, the shift registers can be cascaded such that there are two pairs of cascaded shift register/arrays each pair with one serial input and one serial output requiring only one pin per array. Each of the shift registers is operable to be tapped at any output location therein. The location is determined from a decoded address which is received from the column decode line, thus requiring no additional decoding circuit to determine the tap point. Circuitry is provided to allow separate writing to locations in the four arrays without requiring separate decoding circuits. All four arrays share the same row and column decoders. The circuitry uses either a Write Mask format or separate column address strobes. Either feature can be utilized by selecting a metal mask option for the feature prior to fabrication of the device. Circuitry is also provided for allowing transfer of data from memory to shift register during the last cycle of the shift clock such that new data can immediately follow the old data without requiring the shifting operation to be temporarily terminated.

Although the preferred embodiment has been described in detail, it should be understood that various changes, substitutions and alterations can be made therein without departing from the spirit and scope of the invention as defined by the appended claims. 

What is claimed is:
 1. A semiconductor memory for storing pixel information for a video display, comprising;a first memory array having a plurality of memory elements arranged in rows and columns and associated with a predetermined pixel locations in the display; a second memory array having a plurality of memory elements arranged in rows and columns and associated with predetermined pixel locations on the display said first and second memory arrays being identical; row decode means for receiving a row address and selecting one of the rows of memory elements in both said first and second memory arrays; first serial access means for storing data from the selected memory elements of said first memory array in a serial format; said second serial access means for storing data from selected memory elements of said second memory array in a serial format; said first and second serial access means having a separate serial input and a separate serial output and controlled from an external source to serially shift data therethrough; transfer means for transferring data from the selected memory elements at said first and second array to the respective one of said first and second serial access means or from said serial access means to the selected memory elements in said first and second array; and means for configuring said first and second access means to each circulate data from the serial output to serial input thereof or to cascade said first and second serial access means with the serial output of said first serial access means connected to the serial input of said second serial access means.
 2. The semiconductor memory of claim 1 and further comprising:column decode means for receiving a column address and selecting one of the columns of memory elements in both said first and second memory arrays; and random read/write means for inputting data to the selected one of the memory elements in both said first and second memory arrays as defined by the row and column addresses.
 3. The semiconductor memory of claim 1 wherein said first and second serial access means comprise serial shift registers having a plurality of shift bits equal in number to the number of columns in the respective one of said first and second memory arrays, each of the selected memory elements in the respective one of said first and second memory arrays transferred to the respective one of said shift bits by said transfer means.
 4. The semiconductor memory of claim 1 and further comprising first and second interface means for interfacing between said first and second access means and external peripheral circuitry with respect to the memory, said means for configuring further comprising means for multiplexing the operation of said first and second access means when configured to circulate data such that said first interface means associated with said first access means and multiplexed to either input serial data to said first access means or receive serial data output therefrom and said second interface means associated with said second access means and multiplexed to either input serial data thereto or received serial output data therefrom, said first interface means inputting serial data to said first serial access means when configured in the cascaded mode and said second interface means receiving serial output data from said second serial access means.
 5. The semiconductor memory of claim 1 wherein said configuring means comprises first switch means having first and second positions, said first position operable to connect the serial output of said first access means to the serial input thereof, said second position operable to connect the serial output of said first access means to the serial input of said second access means; andsecond switch means having first and second positions, said first position operable to connect the output of said serial access means to the serial input thereof, said second position operable to inhibit circulation of data from the serial output of said second serial access means to the serial input thereof; and means for configuring said first and second switches in either said first position or said second position.
 6. The semiconductor memory of claim 5 and further comprising:first interface means for interfacing between peripheral circuitry external to the semiconductor memory and the serial input of said first access means; and second interface means for interfacing between the circuitry external to the semiconductor memory and the serial output of said second access means.
 7. The semiconductor memory of claim 5 wherein said first and second switches are programmed in either said first state or said second state as a mask option during fabrication of the semiconductor memory.
 8. A semiconductor memory for storing pixel information for a video display, comprising:a first memory array having a plurality of memory elements arranged in rows and columns and associated with predetermined pixel locations on display; a second memory having a plurality of memory elements arranged in rows and columns and associated with predetermined pixel locations on the display said first and second memory arrays being identical; row access means for receiving a row address and selecting one of the rows of memory elements in both of said first and second memory arrays in response to receiving the row address; first serial shifting means for storing the data from the selected memory element of said first memory array in a serial format and arranged according to the order of the columns in each of the first and second memory arrays; second serial shifting means for storing the data from the selected memory elements of said second memory array in a serial format and arranged according to the order of the columns; said first and second serial shifting means having a serial input and a serial output, serial shifting of data through said first and second shifting means controlled from an external source to serially shift data therethrough; the serial output of said first serial shifting means connected to the serial input of said second serial shifting means to provide a cascaded configuration; and transfer means for transferring data from the selected memory elements in said first and second arrays to the respective one of said first and second shifting means or from said first and second shifting means the respective one of said first and second arrays; said first serial shifting means having the serial input thereof interfaced with circuitry external to the semiconductor memory through a first dedicated port and the serial output of said second serial shifting means having the serial output thereof interfaced with the circuitry external to the semiconductor memory through a second dedicated output port.
 9. The semiconductor memory of claim 8 wherein said first and second serial shifting means comprise serial shift register having a plurality of shift bits therein having a number equal to the number of columns in each of said first and second memory arrays, the input of each of the shift bits connected to the output of an associated one of the columns in the respective one of the first and second memory arrays in response to data transfer by said transfer means.
 10. A semiconductor memory for storing pixel information for a video display, comprising:a first memory array having a plurality of memory elements arranged in rows and columns and associated with predetermined pixel locations on the display; a second memory having a plurality of memory elements arranged in rows and columns and associated with predetermined pixel locations on the display said first and second memory arrays being identical; row access means for receiving a row address and simultaneously selecting one of the rows of memory elements in both said first and second memory arrays; first serial access means for storing the data from the selected memory elements of said first memory array in a serial format and arranged in the order of the columns; second serial shifting means for storing data from the selected memory elements of said second memory array in a serial format according to the order of the columns therein; said first and second shifting means having a serial input and a serial output and shifting therein controlled from an external source to serially shift data therethrough; first multiplexing means for multiplexing the serial input and output of said first shifting means with an external port that interfaces circuitry external to the semiconductor memory with the internal operation thereof; said multiplexing means for connecting either the serial input or output of said second shifting means with a second interface port that interfaces circuitry external to the semiconductor memory with functions internal thereof; said first and second multiplexing means operated by a single signal from an external source with respect to the semiconductor memory such that either both the serial inputs or both the serial outputs can be selected; and transfer means for transferring data from the selected memory elements in said first and second array to the respective one of said first and second shifting means or transferring data from said first and second shifting means to the respective one of said first and second arrays.
 11. The semiconductor memory of claim 10 wherein said shifting means comprises serial shift registers having a plurality of shift bits therein, the input of each of the shift bits associated with one of the columns in the respective one of said first and second arrays for receiving data therefrom or transferring data thereto in response to said transfer means. 